@article{54ef8a13baeb4bd2939fb082bacc875b,
title = "Dynamic land cover evapotranspiration model algorithm: DyLEMa",
abstract = "This study presents the “Dynamic Land Cover Evapotranspiration Model Algorithm: DyLEMa” for continuous spatiotemporal evapotranspiration (ET) estimates across diverse land uses. DyLEMa employs a coupled Random Forest model with a novel dynamic recalibrating strategy to improve pre-optimized seasonal hyperparameters following satellite acquisition alongside land cover classes. An analysis of feature importance indicated the significant variability in ET processes across different land cover classes and seasons. Hence, DyLEMa was applied to 20 years of daily 30x30 m pixel resolution Landsat-derived ET data in Illinois to address spatial and temporal discontinuities due to cloud contamination and sensor failures. DyLEMa performance was evaluated on Eddy Covariance measurements to find out that DyLEMa predictions reduced the average PBIAS error from + 31 % to −7% compared to existing US Geological Survey ET products. Spatially, DyLEMa underscores the value of a land cover-aware approach in ET estimation under varied cloud cover rates and their ability to preserve landscape features. However, the performance of DyLEMa was affected by the quality of land cover classification, suggesting the need for a refined region-specific land cover classification. DyLEMa's flexibility and performance suggest its applicability to other regions and satellite datasets, offering a promising reduction in uncertainty of ET estimates with impacts on environmental and water resources assessments on regional scales.",
keywords = "Decision tree, Evapotranspiration, Resolution tradeoffs, Satellite remote sensing",
author = "Jeongho Han and Guzman, {Jorge A.} and Chu, {Maria L.}",
note = "The US Department of Agriculture funded this research - National Institute for Food and Agriculture ( NIFA ) award number 2019-67019-29884 . This research used the Delta advanced computing and data resource, which is supported by the National Science Foundation (award OAC 2005572 ) and the State of Illinois , as well as the Delta system at the National Center for Supercomputing Applications (NCSA) through allocation [ EES220062 ] from the Advanced Cyberinfrastructure Coordination Ecosystem: Services & Support (ACCESS) program, which National Science Foundation supports grants # 2138259 , # 2138286 , # 2138307 , # 2137603 , and # 2138296 . This research also used the Illinois Campus Cluster, a computing resource operated by the Illinois Campus Cluster Program (ICCP) in conjunction with NCSA and supported by funds from the University of Illinois at Urbana-Champaign. Implementing DyLEMa in Illinois for over 20 years entailed processing billions of satellite pixels to train and predict missing ET values. To manage these computational tasks, we implemented DyLEMa on three high-performance computing (HPC) systems: the Delta system provided through the Advanced Cyberinfrastructure Coordination Ecosystem: Services & Support (ACCESS) program at the National Center for Supercomputing Applications (University of Illinois, NCSA); the Illinois Campus Cluster operated by the Illinois Campus Cluster Program (ICCP) in collaborated with NCSA; and dedicated computing, and data and computing nodes of the Watershed-Ecosystem Research Laboratory (WERL) at the Agricultural and Biological Engineering Department, University of Illinois, funded by USDA-NIFA grant under the Data Science for Food and Agriculture Systems (DSFAS) program. While specifications of these HPC systems differ, an average job runtime across Illinois required approximately 5,760 core hours per year of ET estimates on computing nodes based on double processors AMD Milan and Rome, and datasets storage need for preprocessing and final ET estimates spans over 1 PB.",
year = "2024",
month = may,
doi = "10.1016/j.compag.2024.108875",
language = "English (US)",
volume = "220",
journal = "Computers and Electronics in Agriculture",
issn = "0168-1699",
publisher = "Elsevier B.V.",
}